Analytical and numerical studies were made of single point moorings of a large disc buoy in deep water. Waves of different frequencies and winds of different magnitudes were imposed on moorings of different scopes for nylon ropes. The numerical model results compared favorably with analytical solutions for a straight vibrating string and the buoy motion was validated with the results from a hydraulic model study., by John H. Nath., "August 1970.", Includes bibliographical references (pages 39-40), Prepared for Office of Naval Research N00014-67-A-0299-0009, Print version record.
by Ron R. Robinson., "May 1963.", "Preliminary Progress Report - for the record (Data from this report are to be extracted for publication).", Includes bibliographical references., CER63RRR38., This work was supported by the National Science Foundation Grant NSF G-23706, Print version record.
Equilibrium of alluvial streams has been thoroughly studied in the past century. Many investigators have extended analysis to explain meandering (or braiding) of streams, and attempted to describe the hydraulic geometry of alluvial streams. This study points at the derivation of the characteristics of alluvial streams from fundamental principles. More precisely, this research aims to determine the downstream geometry of alluvial streams (channel width, depth, velocity, slope and radius of curvature), as a function of sediment size and water discharge., by Pierre Y. Julien and Daryl B. Simons., "April, 1984. Revised, February 1985." -- Added title page., "CER83-84PYJ-DBS45.", Includes bibliographical references (leaves 29-40)., Print version record.
"Summer 1996.", "This research was supported by the Department of Defense Geosciences, project, funded under DoD grant #DAAH04-94-G-0402."--P. iv., Includes bibliographic references (p. 86-88)., Mode of access: World Wide Web.
by Richard A. Schleusener., "A summary of the verbal report presented to the Engineering Committee of the Upper Colorado River Basin on 20 July 1961.", CER61RAS45., Print version record.
This study will investigate minimum streamflow and sediment transport In the Yampa Canyon In northwestern Colorado The historic sediment load will I be analyzed for the period of record for the available gaging station will I be analyzed for the period of record for the available gaging station Monument has been previously proposed by the National Park Service. This study will I examine that hydrograph and test possible alternative minimum stream flow hydrographs. These minimum streamflow hydrographs will be evaluated for their effect on sediment supply to the canyon and sediment transport through the canyon., submitted to Nature Conservancy ; J. S. O'Brien., "February 1987.", Bibliography: page 21., Online resource; title from PDF cover (viewed April 2018)
"Preparation of this report has been financially supported by NOAA NESS Grant 04-3-158-51.", "May 1974.", Includes bibliographical references (p. 74-77, 91), Mode of access: World Wide Web.
Soil erosion by rainfall is one of the major sources of sediments transported into streams. The physical processes governing rainfall erosion are very complex and no generally accepted sediment transport equation has been developed so far. Various approaches have been used in the past decades to analyze sediment transport by overland flow., by Pierre Y. Julien and Daryl B. Simons., "CER83-84PYJ-DBS52.", "June, 1984. Revised, February 1985." -- Added title page., Print version record.
by Richard A. Schleusener., "August 1963.", "Research supported by the Atmospheric Sciences Program National Science Foundation.", Final report, NSF Grant G-17964, CER63RAS34, Print version record.
Accidental releases of Hydrogen Fluoride (HF) can result in initially dense gas clouds that will typically contain a mixture of gases, aerosols and droplets which can be transported significant distances before lower hazard levels of HF concentration are reached. Containment fences, vapor barriers, and water-spray curtains have been proposed as a means to hold-up or delay cloud expansion, elevate the plume downwind of the barriers, enhance cloud dilution, and/or remove HF from the gas cloud by deposition., Robert N. Meroney, [and 5 others], Fluid Mechanics and Wind Engineering Program, Civil Engineering Department, College of Engineering, Colorado State University for Exxon Research and Engineering Company ... on behalf of An Industry Cooperative HF Mitigation Program, Vapor Barrier Subcommittee., "July 1988 (Revised February 1989.", Includes bibliographical references (pages 153-159)., CER88-89RNM-DEN-SHS-TS-TZT-GW-1., Print version record.
L.R. Rittenhouse, E.T. Bartlett and L.R. Roath., "10/92.", Includes bibliographical references., Online resource; title from PDF caption (viewed February 2020)
